Process for producing N-phosphonomethylglycine

Process for producing N-phosphonomethylglycine
US4853159

A process for producing N-phosphonomethylglycine by the oxidation of N-phosphonomethyliminodiacetic acid using a molecular oxygen-containing gas in the presence of a transition metal catalyst.

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Patent 4853159
Priority Oct 26 1987
Filed Oct 26 1987
Issued Aug 01 1989
Expiry Oct 26 2007
Inventors Riley, Den…
Assg.orig Monsanto C…
Assg.curr MONSANTO T…
Entity Large
Referenced by 17
References 8
Maint.: all paid

FIELD OF THE INVENTI…
SUMMARY OF RELATED A…
SUMMARY OF THE INVEN…
DETAILED DESCRIPTION…
EXAMPLES
EXAMPLES 1 THROUGH 8
EXAMPLES 9 THROUGH 13
EXAMPLES 14 THROUGH …
EXAMPLES 17 THROUGH …
EXAMPLES 23 THROUGH …
EXAMPLES 30 THROUGH …
EXAMPLES 43 THROUGH …
EXAMPLES 66 THROUGH …
EXAMPLES 86 THROUGH …
EXAMPLES 107-109
EXAMPLES 110 AND 111

1. A process for the production of N-phosphonoglycine which comprises contacting N-phosphonomethyliminodiacetic acid with a molecular oxygen-containing gas in the presence of aqueous solvent, and a catalyst selected from the group consisting of salts and salt complexes of cobalt.

2. A process of claim 1 wherein the molecular oxygen-containing gas is at a partial pressure of oxygen between about 1 psig (6.9 kPa) to about 3000 psig (20,700 kPa).

3. A process of claim 2 wherein the N-phosphonomethyliminodiacetic acid is contracted with the molecular oxygen-containing gas at an initial pH between about 0.1 and about 7∅

4. A process of claim 3 wherein the N-phosphonomethyliminodiacetic acid is contacted with the molecular oxygen-containing gas at a temperature between about 25°C and 150°C

5. A process of claim 4 wherein the catalyst is selected from the group consisting of cobalt chloride, cobalt bromide, cobalt sulfate, cobalt bis(acetylacetonate) and cobalt acetate.

FIELD OF THE INVENTION

This invention relates to a process for producing N-phosphonomethylglycine by the oxidation of N-phosphonomethyliminodiacetic acid using transition metal catalysts. More particularly, this invention relates to a reaction using molecular oxygen and a transition metal salt catalyst.

SUMMARY OF RELATED ART

It is known in the art that N-phosphonomethylglycine can be produced by oxidizing N-phosphonomethyliminodiacetic acid using various oxidizing methods. U.S. Pat. No. 3,950,402 discloses a method wherein N-phosphonomethyliminodiacetic acid is oxidized to N-phosphonomethylglycine in aqueous media using a free oxygen-containing gas and a heterogeneous noble metal-based catalyst such as palladium, platinum or rhodium. U.S. Pat. No. 3,954,848 discloses the oxidation of N-phosphonomethyliminodiacetic acid with hydrogen peroxide and an acid such as sulfuric or acetic acid. U.S. Pat. No. 3,969,398 discloses the oxidation of N-phosphonomethyliminodiacetic acid using molecular oxygen and a heterogeneous activated carbon catalyst. Hungarian Patent Application No. 011706 discloses the oxidation of N-phosphonomethyliminodiacetic acid with peroxide in the presence of metals or metal compounds.

R. J. Motekaitis, A. E. Martell, D. Hayes and W. W. Frenier, Can. J. Chem., 58, 1999 (1980) disclose the iron(III) or copper(II) catalysed oxidative dealkylation of ethylene diaminetetracetic acid (EDTA) and nitrilotriacetic acid (NTA), both of which have iminodiacetic acid groups. R. J. Moteakitis, X. B. Cox, III, P. Taylor, A. E. Martell, B. Miles and T. J. Tvedt, Can. J. Chem., 60, 1207 (1982) disclose that certain metal ions, such as Ca(II), Mg(II), Fe(II), Zn(II) and Ni(II) chelate with EDTA and stabilized against oxidation, thereby reducing the rate of oxidative dealkylation.

SUMMARY OF THE INVENTION

The present invention involves a process for the production of N-phosphonomethylglycine comprising contacting N-phosphonomethyliminodiacetic acid with a molecular oxygen-containing gas in the presence of a transition metal catalyst.

DETAILED DESCRIPTION OF THE INVENTION

The process of this invention involves contacting N-phosphonomethyliminodiacetic acid with a transition metal catalyst in a mixture or solution. This mixture or solution is contacted with a molecular oxygen-containing gas while heating the reaction mass to a temperature sufficiently elevated to initiate and sustain the oxidation reaction of N-phosphonomethyliminodiacetic acid to produce N-phosphonomethylglycine.

The transition metal catalyst of the present invention can be any one or more of several transition metal compounds such as manganese, cobalt, iron, nickel, chromium, ruthenium, aluminum, molybdenum, vanadium and cerium. The catalysts can be in the form of salts such as manganese salts, e.g., manganese acetate, manganese sulfate; complexes such as manganese(II)bis(acetylacetonate) (Mn(II)(acac)₂); cobalt salts such as Co(II)(SO₄), Co(II)(acetylacetonate), CoCl₂, CoBr₂, Co(NO₃)₂ and cobalt acetate; cerium salts such as (NH₄)₄ Ce(SO₄) and (NH₄)₂ Ce(NO₃)₆, iron salts such as (NH₄)₂ Fe(SO₄)₂, iron(III)(dicyano)-(bisphenanthroline)₂ -(tetrafluoro)borate salt and K₃ Fe(CN)₆, and other metal salts such as NiBr₂, CrCl₃, RuCl₂ (Me₂ SO), RuBr₃, Al(NO₃)₃, K₄ Mo(CN)₈, VO(acetylacetonate)₂ and VOSO₄. The catalyst can be added to the N-phosphonomethyliminodiacetic acid in the salt form, or a salt may be generated in situ by the addition of a source of a transition metal ion such as MnO₂ which dissolves in the reaction medium. The Mn(III)chloro(phthalocyaninato), however, is not catalytic, possibly because the phthalocyanine ligand covalently bonds to the Mn(III) and therefore inhibits the formation of N-phosphonomethyliminodiacetic acid/ manganese complex in solution.

Manganese salts such as Mn(II), Mn(III) or Mn(IV) salts can be used individually, however, the reaction displays a delayed reaction initiation time (initiation period), e.g., there is a delay before any N-phosphonomethylglycine is produced. When a mixture of Mn(II) and Mn(III) salts are used as a catalyst system, the initiation is diminished or eliminated. A preferred manganese salt catalyst is a mixture of Mn(II) and Mn(III) salts in the range of 1:10 to 10:1 mole ratio of the Mn ions. A most preferred manganese catalyst salt is a 1:1 mole ratio of Mn(II) and Mn(III) ions in the form of manganese acetate salts. A preferred cobalt catalyst is a Co(II) salt such as Co(II)(SO₄), Co(II)Cl₂, Co(II)Br₂, Co(II)(OH)₂ and Co(II)acetate.

The concentration of the transition metal catalyst in the reaction solution can vary widely, in the range of 0.1M to 0.0001M total metal ion concentration. For manganese, the reaction appears to have a first order dependency on the catalyst concentration, e.g., the reaction rate increases linearly as the catalyst concentration increases. The preferred concentration is in the range of about 0.01M to about 0.001M, which gives a suitably fast rate of reaction that can be easily controlled and favors selectivity to N-phosphonomethylglycine.

The reaction temperature is sufficient to initiate and sustain the oxidation reaction, in the range of about 25°C to 150°C In general, as the reaction temperature increases, the reaction rate increases. To achieve an easily controlled reaction rate and favor selectivity to N-phosphonomethylglycine, a preferred temperature range is about 50°C to 120°C and a most preferred is in the range of about 70°C to 100°C If a temperature of above about 100°C is used, pressure will have to be maintained on the system to maintain a liquid phase.

The pressure at which this process is conducted can vary over a wide range. The range can vary from about atmospheric (101 kPa) to about 3000 psig (207600 kPa). A preferred range is about 30 psig (200 kPa) to about 1000 psig (about 6900 kPa). A most preferred range is from about 150 psig (about 1000 kPa) to 600 psig (about 4140 kPa).

The oxygen concentration, as designated by the partial pressure of oxygen (PO₂), in the reaction affects the reaction rate and the selectivity to the desired product, N-phosphonomethylglycine. As the PO₂ increases, the reaction rate generally increases and the selectivity to N-phosphonomethylglycine increases. The PO₂ can be increased by increasing the overall reaction pressure, or by increasing the molecular oxygen concentration in the molecular oxygen-containing gas. The PO₂ can vary widely, in the range of from 1 psig (6.9 kPa) to 3000 psig (20700 kPa). A preferred range is from 30 psig (207 kPa) to 1000 psig (6900 kPa).

The term "molecular oxygen-containing gas" means molecular oxygen gas or any gaseous mixture containing molecular oxygen with one or more diluents which are non-reactive with the oxygen or with the reactant or product under the conditions of reaction. Examples of such diluent gases are air, helium, argon, nitrogen, or other inert gas, or oxygen-hydrocarbon mixtures. A preferred molecular oxygen is undiluted oxygen gas.

The manner in which the solution or mixture of the N-phosphonomethyliminodiacetic acid is contacted with molecular oxygen can vary greatly. For example, the N-phosphonomethyliminodiacetic acid solution or mixture can be placed in a closed container with some free space containing molecular oxygen and shaken vigorously or agitated by stirring. Alternatively, the molecular oxygen can be continuously bubbled through the solution or mixture containing the transition metal catalyst using a straight tube or a tube with a fritted diffuser attached to it. The process of this invention only requires actively contacting the molecular oxygencontaining gas with the aqueous solution or mixture of the N-phosphonomethyliminodiacetic acid containing a transition metal catalyst.

The initial pH (pHi) of the reaction affects the reaction rate and the selectivity to N-phosphonomethylglycine. For example, with manganese, as the initial pH increases, the reaction rate increases, but the selectivity to N-phosphonomethylglycine decreases. The pHi of the reaction can vary widely, in the range of about 0.1 to about 7. A preferred range is about 1 to about 3 with mangnaese and about 0.1 to 3 with cobalt. A most preferred pH is the unadjusted pH of N-phosphonomethyliminodiacetic acid in a water solution which varies with the N-phosphonomethyliminodiacetic acid concentration and the reaction temperature.

The oxidation reaction can take place in a solution or slurry. For a solution, the initial concentration of the N-phosphonomethyliminodiacetic acid in the reaction mass is a function of the solubility of the N-phosphonomethyliminodiacetic acid in a solvent at both the desired reaction temperature and the pHi of the solution. As the solvent temperature and pH changes, the solubility of the N-phosphonomethyliminodiacetic acid changes. A preferred initial concentration of the N-phosphonomethyliminodiacetic acid is a saturated slurry containing a solvent system at reaction conditions, which maximizes the yield of N-phosphonomethylglycine in the reaction mass. A preferred concentration of N-phosphonomethyliminodiacetic acid is in the range of about 1 to 50 wt. %. It is, of course, possible to employ very dilute solutions of N-phosphonomethyliminodiacetic acid, or slurries and mixtures.

The reaction is typically carried out in an aqueous solvent. The term aqueous solvent means solutions containing at least about 50 weight % water. The preferred aqueous solvent is distilled, deionized water.

The following examples are for illustration purposes only and are not intended to limit the scope of the claimed invention.

EXAMPLES

A series of runs were made to oxidize N-phosphonomethyliminodiacetic acid to N-phosphonomethylglycine. The reactions were conducted in a modified Fisher-Porter glass pressure apparatus or an Engineer Autoclave 300 ml pressure reactor in which a stirrer was installed in the head, as were three additional valved ports that were used as a sample port, a gas inlet, and a purged gas outlet. The stirrer maintained sufficient agitation to afford thorough gas-liquid mixing. The temperature was controlled by immersing the reactor in a constant temperature oil bath. The indicated amount of transition metal catalyst was dissolved or suspended in a distilled, deionized water solution containing the indicated amount of N-phosphonomethyliminodiacetic acid. The reactor was sealed and heated to the indicated reaction temperature, then pressurized to the indicated PO₂ with oxygen gas. Agitation was initiated.

The selectivity (mole %) to N-phosphonomethylglycine was determined by dividing the moles of N-phosphonomethylglycine produced by the total moles of N-phophonomethyliminodiacetic acid consumed and multiplying by 100. The yield (mole %) of N-phosphonomethylglycine was determined by dividing the moles of N-phosphonomethylglycine produced by the total moles of starting M-phosphonomethyliminodiacetic acid and multiplying by 100.

EXAMPLES 1 THROUGH 8

Examples 1 through 8, shown in Table 1, show the effect of varying the manganese catalyst concentration. In examples 1-4 the reaction temperature was 90°C, the PO₂ was 100 psig (690 kPa), the initial N-phosphonomethyliminodiacetic acid concentration was 0.1M. The catalyst was a mixture of Mn(II) and Mn(III) acetate salts in a 1:1 mole ratio of Mn(II) and Mn(III). Examples 5-8 were run at the same conditions as 1-4, except that the PO₂ was 450 psig (3100 kPa) and the reaction temperature was 80°C and the catalyst was Mn(II) acetate.

TABLE 1

______________________________________

Effect of Varying Catalyst Concentration

Yield of

Selectivity Initial N--Phosphono-

to N--phospho

Manganese Reaction

methyl glycine

Ex- nomethyl- Concen- Rate (Male %)

am- glycine tration (Velocity,

at indi-

ples (Mole %) (M) M/hr) cated time (h)

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1 58 0.008 0.23 53(6)

2 82 0.004 0.10 75(6)

3 84 0.002 0.05 18(11/4)

4 63 0.001 0.016 45(6)

5 83 0.02 0.30 83(2/3)

6 83 0.0067 0.10 81(1/2)

7 70 0.004 0.07 68(6)

8 74 0.002 0.034 68(6)

______________________________________

The data indicated that the reaction rate increases with the catalyst concentration. There appeared to be a first-order dependence of the reaction rate on the catalyst concentration.

EXAMPLES 9 THROUGH 13

Examples 9 through 13, shown in Table 2, illustrate the effect of initial pH on the reaction rate and selectivity to N-phosphonomethylglycine for a manganese catalyst. The reaction temperature was 80°C, the PO₂ was 100 psig (690 kPa), the initial N-phosphonomethyliminodiacetic acid concentration was 0.1M, the reaction times are indicated and the manganese ion concentration was 0.004M. The mixture of manganese salts was the same as used in Example 1. The initial pH was adjusted using sodium hydroxide or sulfuric acid solutions. THe data indicate that as the initial pH increases, the reaction rate increases, but the selectivity to N-phosphonomethylglycine decreases.

TABLE 2

______________________________________

Effect of Varying Initial pH

Yield of Selectivity

Initial N--phosphonomethyl

to N--phos-

Reaction glycine (Mole %)

phonomethyl

Exam- Initial Rate at indicated time

glycine

ple pH (M/h) (h) (Mole %)(h)

______________________________________

9 1.20 0.0103 31(6) 49(6)

10 1.35 0.015 56(5) 66(5)

11 1.80 0.11 41(21/2) 44(21/2)

12 2.30 0.14 36(21/2) 37(21/2)

13 3.50 0.32 39(39) 41(1/2)

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EXAMPLES 14 THROUGH 16

Examples 14 through 16, shown in Table 3, illustrate the effect of reaction temperature on reaction rates and selectivity to N-phosphonomethyl glycine for a manganese catalyst. The PO₂ was 450 psig, the initial N-phosphonomethyliminodiacetic acid concentration was 0.1M and the manganese ion concentration was 0.067M. The form of the manganese salt was Mn(II)SO₄. and the pH was the unadjusted pH of the acid solution.

The data indicated that as the reaction temperature increased, the reaction rate increased.

TABLE 3

______________________________________

Effect of Varying Temperature

Selectivity to

N--phosphono-

Yield

methyl of N--phosphono-

Initial glycine methyl glycine

Temper- Reaction (Mole %) at

(Mole %) at

Exam- ature Rate indicated indicated time

ple (°C.)

(M/hr) time (h) (h)

______________________________________

14 70 0.035 77 (5) 75(5)

15 80 0.093 83 (11/2) 81(11/2)

16 90 0.310 80 (1/2) 77(1/2)

______________________________________

EXAMPLES 17 THROUGH 22

Examples 17 through 22, shown in Table 4, illustrate the effect of PO₂ on selectivity to N-phosphonomethylglycine for a manganese catalyst. The reaction temperature was 80°C, the initial N-phosphonomethyliminodiacetic acid concentration was 0.1, the reaction time was as indicated which allowed for almost complete conversion of the N-phosphonomethyliminodiacetic acid, and the manganese ion concentration was 0.006M. The form of the manganese salt was Mn(II)SO₄ and the pHi was the unadjusted pH of the acid solution.

The data indicated that as the PO₂ increased, the selectivity to N-phosphonomethylglycine increased.

TABLE 4

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Effect of Varying PO₂

Yield of

N--phospho-

Selectivity nomethyl

to N--phosphono-

glycine

methyl glycine

(Mole %)

(Mole %) at the

PO₂ at the indica-

indicated

Example psig (kPa) ted time (h) time (h)

______________________________________

17 40(210) 56(6) 54(6)

18 70(450) 65(6) 63(6)

19 100(690) 68(6) 66(6)

20 130(890) 75(6) 73(6)

21 225(1550) 81(2) 78(2)

22 450(3100) 83(11/2) 81(11/2)

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EXAMPLES 23 THROUGH 29 AND CONTROL 1

Examples 23 through 29 and Control 1, shown in Table 5, illustrate the effect of varying the form of the manganese catalyst on selectivity to N-phosphonomethylglycine. The reaction temperature was 90°C, the PO₂ was 100 psig (700 kPa), the initial concentration of N-phosphonomethyliminodiacetic acid was 0.1M, the manganese concentration was 0.004M and the reaction time was 1 h. The pHi was the unadjusted pH of the acid solution.

The Mn(III)chloro-(phthalocyaninato) (Control 1) was not catalytic.

TABLE 5

______________________________________

Effect of Varying Form of Manganese

Selectivity to

N--phosphonomethyl

glycine (Mole %)

Selectivity

Example

Form at 1 h. at 6 h.

______________________________________

23 ¹ Mn(II)/Mn(III)

43 75

24 Mn(II)acetate

18 75

25 Mn(III)acetate

20 75

26 Mn(II)sulfate

16 75

27 ² Mn(II)(acac)

20 75

28 ³ MnCl₂.4H₂ O

82 --

29 ³ MnO₂

70 73

Control

⁴ Mn(III)

1 <10

______________________________________

¹ Mn acetate, 50/50 mole ratio Mn(II)/Mn(III)

² Mn(II)bis(acetylacetonate)

³ PO₂ = 450 psig (3100 kPa) at 80°C and Mn

concentration was 0.0lM.

⁴ Mn(III)chloro-(phthalocyanato)

EXAMPLES 30 THROUGH 42

Examples 30 through 42, shown in Table 6, further illustrate the present invention. The initial pH, unless otherwise indicated, was the unadjusted pH at reaction temperature, the PO₂, unless otherwise indicated, is 100 psig (690 kPa), the initial concentration of N-phosphonomethyliminodiacetic acid was 0.1M, and the manganese catalyst was the mixture used in Example 1.

TABLE 6

__________________________________________________________________________

Run Time

Catalyst Temperature

Yield Conversion

Example

(h) Concentration(M)

(°C.)

(Mole %)

__________________________________________________________________________

30 1 .01 90 10 96

31 1 .02 80 42 97

32 l^a

.007 80 32 91

33 2 .01 70 8 95

34 2 .007 80 65 95

35 2^b

.007 70 74 96

36 2^c

.007 80 25 75

37 2^d

.007 80 22 63

38 2 .004 90 42 80

39 2 .002 90 60 75

40^e

21/2 .007 80 85 100

41^f

1 .007 80 95 97

42^g

5 .07 80 19 84

__________________________________________________________________________

^a pHi = 2.3

^b PO₂ = 130 psig(810 kPa)

^c PO₂ = 40 psig(275 kPa)

^d pHi = 1.35

^e PO₂ = 225 psig(1545 kPa)

^f PO₂ = 450 psig (3100 kPa)

^g Catalyst was Mn(II)acetylacetonate, the PO₂ was 450 psi(3000

kPa) and the initial concentration of N--phosphonomethyliminodiacetic aci

was 0.5M.

EXAMPLES 43 THROUGH 65

Examples 43 through 65, shown in Table 7, illustrate the use of cobalt catalysts in the present invention. The initial concentration of N-phosphonomethiminodiacetic acid was 0.1M and the catalyst was Co(II)(SO₄). The pH was the unadjusted pH of the N-phosphonomethyliminodiacetic acid of the solution, unless otherwise indicated when it was adjusted with sodium hydroxide or sulfuric acid solution.

TABLE 7

__________________________________________________________________________

Cobalt Catalysts

Catalyst

Run Time

Concentration

Temperature

Yield Conversion

Example

(h) (M) (°C.)

(Mole %)

pH PO₂ (psi)

__________________________________________________________________________

43 5.5 0.02 80 73 100 unadjusted

450

44 3.0 0.02 85 85 100 " 450

45 1.75 0.02 90 75 100 " 450

46 5.5 0.02 85 90 100 " 450

47 5 0.02 85 98 100 " 1000

48 2.0^a

0.02 85 21 31 " 450

49 5.5 0.02 85 74 98 " 300

50 3.0^b

0.036 90 87 100 " 450

51 4.0^c

0.048 80 64 97 " 450

52 5.0^d

0.125 85 52 99 " 450

53 18^f

0.5 100 16 100 6.25 100

54 18^e

0.5 100 28 98 1.80 100

55 18^e

0.5 100 16 100 2.25 100

56 18^e

0.5 100 0 100 4.00 100

57 18^e

0.5 100 35 98 1.09 100

58 18^e

0.5 100 9.9 22 0.77 100

59 18^e

0.5 100 17 98 1.7 100

60 18^e

0 100 0 98 9.00 100

61 18^e

0.01 100 20 40 0.44 100

62 2^f

0.01 100 28 98 1.80 100

63 2^g

0.01 100 26 98 1.80 100

64 18^h

0.01 100 26 98 1.74 100

65 5ⁱ

0.2 85 66 99 1.7M 450

__________________________________________________________________________

^a The catalyst was Co(III)(acetylacetonate)₃.

^b The initial N-phosphonomethyliminodiacetic acid concentration was

0.3M.

^c The initial N-phosphonomethyliminodiacetic acid concentration was

0.4M.

^d The initial N-phosphonomethyliminodiacetic acid concentration was

1.0M.

^e The initial N-phosphonomethyliminodiacetic acid concentration was

0.5M, the catalyst was CoCl₂.

^f The initial N-phosphonomethyliminodiacetic acid concentration was

0.5M and the catalyst was Co(NO₃)₂.

^g The initial N-phosphonomethyliminodiacetic acid concentration was

0.5M and the catalyst was cobalt acetate.

^h The initial N-phosphonomethyliminodiacetic acid concentration was

0.5M and the catalyst was CoBr₂.

ⁱ The initial N-phosphonomethyliminodiacetic acid concentration was

0.4M.

EXAMPLES 66 THROUGH 85

Examples 66 through 85, shown in Table 8, illustrate iron catalysts suitable for the present invention. The PO₂ was 100 psi (690 kPa), the catalyst concentration was 0.01M, the reaction temperature was 100°C, the run time was 18 h, and the initial concentration of the N-phosphonomethyliminodiacetic acid was 0.5M, which formed a slurry. When NaBr was added, the concentration was also 0.01 M.

TABLE 8

__________________________________________________________________________

Iron Catalysts

Yield Conversion

Example

Catalyst (mole %)

(mole %)

__________________________________________________________________________

66 Fe(SO₄)₂

21 36 6.25

67 " 18 28 10.0

68 " 6 14 5.0

69 Fe(SO₄)₂ + NaBr

5 6 3.0

70 " 12 14 5.0

71 " 26 40 6.25

72 " 28 84 7.0

73 " 29 84 8.0

74 " 37 83 9.0

75 iron(III)(dicyano)bis

6 12 6.25

(o-phenanthroline) tetrafluoroborate

salt

76 " 8 10 7.0

77 " 3 12 9.0

78 " 3 12 10.0

79 K₃ Fe(CN)₆^a

3 14 3.0

80 " 8 24 5.0

81 " 21 46 6.3

82 " 30 76 7.0

83 " 37 80 9.0

84 " 32 80 10.0

85 Fe(SO₄)₂ + Al(NO₃)₃

21 72 6.0

__________________________________________________________________________

^a Run time is 8 h.

EXAMPLES 86 THROUGH 106 AND CONTROL 2

Examples 86 through 106 and Control 2, shown in Table 9, illustrate nickel, chromium, ruthenium, aluminum, and molybdenum catalysts appropriate for the present invention. The conditions are as for those given in Table 8. The catalyst for Control 2, CuCl₂, appeared to be ineffective.

Table 9

______________________________________

Nickel Chromium, Ruthenium, Aluminum

and Molybdenum Catalysts

Yield Conversion

Examples

Catalyst (mole %) (mole %)

______________________________________

86 NiBr₂ 0.2 22 5.0

87 " 0.2 10 4.0

88 " 10 34 7.0

89 " 9 38 8.4

90 " 8 34 10.4

91 CrCl₃ 1 12 1.26

92 " 4 16 2.0

93 " 16 76 3.0

94 " 0.1 14 4.0

95 " 12 52 5.0

96 " 4 22 7.0

97 " 13 58 6.25

98 RuBr₃ 70 8 6.25

99 " 18 34 10.0

100 RuBr₂ (Me₂ SO)₄

34 62 6.25

101 " 25 48 11.0

102 Al(NO₃)₃

11 34 6.25

103 Al(NO₃)₃ + NaCl

12 16 6.25

Control 2

CuCl₂ 0.2 14 6.25

104 K₄ Mo(CN)₈

4 22 4.0

105 " 32 48 6.0

106 " 10 30 9.0

______________________________________

EXAMPLES 107-109

Examples 107 through 109 shown in Table 10, illustrate vanadium catalysts suitable for the present invention. The reaction temperature was 70°C, the PO₂ was 100 psi (690 kPa), the initial concentration of N-phosphonomethyliminodiacetic acid was 0.5M, the catalyst concentration was 0.033M.

TABLE 10

______________________________________

Vanadium Catalysts

Run

Time Yield Conversion

Examples

Catalyst (h) (mole %)

(mole %)

______________________________________

107 VO(acetylacetonate)₂

2 40 67

108 VOSO₄ (hydrate)

2.25 42 94

109 VOSO₄ (hydrate)^a

5 54 91

______________________________________

^a The initial concentration of N--phosphonomethyliminodiacetic acid

was 0.15 M and the concentration of catalyst was 0.015 M.

EXAMPLES 110 AND 111

Examples 110 and 111 shown in Table 11 illustrate cerium catalysts suitable for the present invention. The reaction temperature was 90°C and the PO₂ was 130 psi (897 kPa).

TABLE 11

__________________________________________________________________________

Cerium Catalysts

N--phosphonomethyl-

Catalyst

iminodiacetic acid

Run Time

Concentration

Yield

Conversion

Example

Catalyst (h) (M) (M) (mole %)

(mole %)

__________________________________________________________________________

110 Ce(NH₄)₄ (SO₄)₄

3 0.1 1.0 7 45

111 Ce(NH₄)₄ (SO₄)₄

3 0.01 0.1 30 80

__________________________________________________________________________

INVENTORS:

Riley, Dennis P., Rivers, Jr., Willie J.

THIS PATENT IS REFERENCED BY THESE PATENTS:

Patent	Priority	Assignee	Title
4898972,	Sep 26 1988	Monsanto Company	Process for producing N-phosphonomethylglycine
4937376,	May 25 1989	Monsanto Company	Process for producing N-phosphonomethylglycine
4952723,	Jul 31 1989	Monsanto Company	Process for producing N-phosphonomethylglycine
5023369,	Jun 25 1990	MONSANTO TECHNOLOGY LLC	Process for producing N-phosphonomethylglycine
5043475,	Jun 25 1990	MONSANTO TECHNOLOGY LLC	Peroxide process for producing N-phosphonomethylglycine
5047579,	Jan 26 1990	MONSANTO TECHNOLOGY LLC	Process for producing n-phosphonomethylglycine
5077430,	Jun 25 1990	MONSANTO TECHNOLOGY LLC	Peroxide process for producing N-phosphonomethylglycine
5077431,	Jun 25 1990	MONSANTO TECHNOLOGY LLC	Peroxide process for producing n-phosphonomethylglycine
5095140,	Jun 25 1990	MONSANTO TECHNOLOGY LLC	Peroxide process for producing N-phosphonomethylglycine
5500485,	Jun 21 1993	Zeneca Limited	Manufacture of N-phosphonomethylglycine and its salts
6867326,	Jul 23 1999	BASF Aktiengesellschaft	Method of producing glyphosate or a salt thereof
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7932419,	Aug 14 2003	MONSANTO TECHNOLOGY LLC	Transition metal-containing catalysts and processes for their preparation and use as oxidation and dehydrogenation catalysts
8198479,	Feb 17 2005	MONSANTO TECHNOLOGY LLC	Transition metal-containing catalysts and catalyst combinations including transition metal-containing catalysts and processes for their preparation and use as oxidation catalysts
8697904,	Aug 14 2003	MONSANTO TECHNOLOGY LLC	Transition metal-containing catalysts and processes for their preparation and use as oxidation and dehydrogenation catalysts
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THIS PATENT REFERENCES THESE PATENTS:

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ASSIGNMENT RECORDS Assignment records on the USPTO

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Executed on	Assignor	Assignee	Conveyance	Frame	Reel	Doc
Oct 21 1987	RILEY, DENNIS P	Monsanto Company	ASSIGNMENT OF ASSIGNORS INTEREST	004775	0786	pdf
Oct 21 1987	RIVERS, WILLIE J JR	Monsanto Company	ASSIGNMENT OF ASSIGNORS INTEREST	004775	0786	pdf
Oct 26 1987		Monsanto Company	(assignment on the face of the patent)
Jun 11 2001	PHARMACIA CORPORATION, FORMERLY KNOWN AS MONSATO COMPANY	MONSANTO TECHNOLOGY LLC	ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS	012350	0224	pdf

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